Deformation Characterization, Twinning Behavior and Mechanical Properties of Dissimilar Friction-Stir-Welded AM60/AZ31 Alloys Joint During the Three-Point Bending

doi:10.1007/s40195-021-01313-2

Abstract

Abstract:

The AZ31 and AM60 alloys were used for dissimilar friction stir welding (FSW) in this study. The microstructure characteristics of the joint and its three-point bending performance were investigated. The electron backscattered diffraction results showed that the grains in the nugget zone (NZ) were more uniform and refined to a certain extent after FSW, but the grain size of AM60 in the NZ was larger than that of AZ31. The texture was strong locally in the NZ and presented a symmetric distribution characteristic from the advancing side to the retreating side. There were special texture features in the joint, resulting in the occurrence of severe strain localization during the bending process compared with the base materials, which can be well explained by the calculated Schmid factor in terms of the assumed stress state for bending. The bending tests revealed that the joint presented good bending properties compared with AZ31 BM. The bending fracture morphologies suggested that the fracture tended to the NZ interface on the AZ31 side, which was mainly due to the higher SF for basal slip and dislocation concentration degree in the region, and the relatively lower bending strength of AZ31 metal.

Key words: Friction stir welding (FSW), Dissimilar joint, Microstructure evolution, Bending properties, Deformation

Junlei Zhang, Han Liu, Xiang Chen, Qin Zou, Guangsheng Huang, Bin Jiang, Aitao Tang, Fusheng Pan. Deformation Characterization, Twinning Behavior and Mechanical Properties of Dissimilar Friction-Stir-Welded AM60/AZ31 Alloys Joint During the Three-Point Bending[J]. Acta Metallurgica Sinica (English Letters), 2022, 35(5): 727-744.

Figures/Tables 20

Fig. 1 Photograph of rotating tool and schematics of FSW

Fig. 2 a Schematic illustration of surface and base bending tests for FSW Mg joint and b distribution of black speck markers on white matrix

Fig. 3 OM and EBSD maps of BMs: a AZ31 BM; b AM60 BM

Fig. 4 Macrostructure of the cross section of joint

Fig. 5 IPF maps in various regions of the joint

Fig. 6 (0001) pole figures in various regions of the joint

Fig. 7 a Stress-strain curves and b fracture morphologies of the BMs and the joint in bending

Table 1 Bending properties of the BMs and joint

Sample	BYS (MPa)	UBS (MPa)	B-EI (%)
AM60	192 ± 2.2	541 ± 3.1	28.2 ± 0.9
AZ31	190 ± 2.7	457 ± 4.2	14.3 ± 0.8
Surface test	171 ± 2.9	476 ± 3.1	24.8 ± 0.4
Base test	166 ± 2.4	471 ± 2.9	22.6 ± 0.7

Fig. 8 Strain distribution of the two BMs: a AM60 BM; b AZ31 BM; c strain component in εX of AM60 BM; d strain component in εX of AZ31 BM

Fig. 9 Strain distribution maps of the joint: a surface test; b base test; c strain component in εX of surface test; d strain component in εX of base test

Fig. 10 SF distributions for extension twinning and basal slip of each region in joint: a flexural stress diagram; b basal slip; c extension twinning for tension; d extension twinning for compression

Fig. 11 Mean SF distributions for extension twinning and basal slip of each region in joint

Fig. 12 EBSD maps of base test sample after bending (corresponding to R1, R2 and R3 in Fig. 13a): a NZ side (AM60 side); b NZ center; c NZ side (AZ31 side)

Fig. 13 Texture evolutions in the various regions of the bending joint after 95% under the maximum bending strength: a base test; b surface test

Fig. 14 EBSD maps of base test sample after 95% under the maximum bending strength

Fig. 15 OM maps of NZ center in the compression zone of the base test sample

Fig. 16 a Schematic illustration of shear layer formation tempted by the rotation of friction stir welding pin; b SF distribution for basal slip in R5 after bending; c SF distribution for basal slip in R1 and R2 after bending; d schematic diagram of extension twinning variants

Fig. 17 EBSD maps of surface test sample after 95% under the maximum bending strength

Fig. 18 EBSD maps of BMs: a AZ31 BM; b AM60 BM

Fig. 19 KAM maps of joint: a AZ31 side; b AM60 side

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